What is JavaScript's highest integer value that a number can go to without losing precision?

Is this defined by the language? Is there a defined maximum? Is it different in different browsers?

• You don't need to depend on JS's limits with libraries like github.com/MikeMcl/big.js, see e.g. here for its reliability tests May 18 '16 at 4:26
• what's the highest integer value you can use with big.js ? Mar 26 '18 at 20:41
• @DmitriZaitsev We don't need to depend on external libraries any more (on some browsers, at least). 1n << 10000n is a really, really big integer, without losing any precision, without requiring any dependencies (and needless to say, not even close to a limit). Jan 6 '20 at 9:12
• @DmitriZaitsev Notice the n suffix. BigInt class is a part of ES2020 spec draft, already implemented in the majority of browsers; you can try to evaluate that in e.g. Chrome or Firefox, with no external libraries, and get a 3011-digit BigInt. Jan 8 '20 at 11:41
• @DmitriZaitsev: Yes, it is only for integers. This question is about integers. Jan 8 '20 at 12:01

JavaScript has two number types: Number and BigInt.

The most frequently-used number type, Number, is a 64-bit floating point IEEE 754 number.

The largest exact integral value of this type is Number.MAX_SAFE_INTEGER, which is:

• 253-1, or
• +/- 9,007,199,254,740,991, or
• nine quadrillion seven trillion one hundred ninety-nine billion two hundred fifty-four million seven hundred forty thousand nine hundred ninety-one

To put this in perspective: one quadrillion bytes is a petabyte (or one thousand terabytes).

"Safe" in this context refers to the ability to represent integers exactly and to correctly compare them.

From the spec:

Note that all the positive and negative integers whose magnitude is no greater than 253 are representable in the Number type (indeed, the integer 0 has two representations, +0 and -0).

To safely use integers larger than this, you need to use BigInt, which has no upper bound.

Note that the bitwise operators and shift operators operate on 32-bit integers, so in that case, the max safe integer is 231-1, or 2,147,483,647.

const log = console.log
var x = 9007199254740992
var y = -x
log(x == x + 1) // true !
log(y == y - 1) // also true !

// Arithmetic operators work, but bitwise/shifts only operate on int32:
log(x / 2)      // 4503599627370496
log(x >> 1)     // 0
log(x | 1)      // 1

Technical note on the subject of the number 9,007,199,254,740,992: There is an exact IEEE-754 representation of this value, and you can assign and read this value from a variable, so for very carefully chosen applications in the domain of integers less than or equal to this value, you could treat this as a maximum value.

In the general case, you must treat this IEEE-754 value as inexact, because it is ambiguous whether it is encoding the logical value 9,007,199,254,740,992 or 9,007,199,254,740,993.

• This seems right, but is there someplace where this is defined, á la C's MAX_INT or Java's Integer.MAX_VALUE? Nov 20 '08 at 23:35
• 4294967295 === Math.pow(2,32) - 1; Aug 23 '11 at 20:15
• So what's the smallest and largest integer we can use to assure exact precision? Oct 15 '11 at 16:21
• Maybe worth noting that there is no actual (int) in javascript. Every instance of Number is (float) or NaN. Aug 31 '12 at 13:09
• 9007199254740992 is not really the maximum value, the last bit here is already assumed to be zero and so you have lost 1 bit of precision. The real safe number is 9007199254740991 ( Number.MAX_SAFE_INTEGER ) Aug 21 '14 at 17:59

>= ES6:

Number.MIN_SAFE_INTEGER;
Number.MAX_SAFE_INTEGER;

<= ES5

From the reference:

Number.MAX_VALUE;
Number.MIN_VALUE;

console.log('MIN_VALUE', Number.MIN_VALUE);
console.log('MAX_VALUE', Number.MAX_VALUE);

console.log('MIN_SAFE_INTEGER', Number.MIN_SAFE_INTEGER); //ES6
console.log('MAX_SAFE_INTEGER', Number.MAX_SAFE_INTEGER); //ES6

• I've edited the question to be a bit more precise about wanting the max Integer values, not just the max Number value. Sorry for the confusion, here. Nov 20 '08 at 23:21
• Is the returned result guaranteed to be equal on all browsers? Sep 21 '13 at 19:05
• Note that Number.MIN_VALUE is the smallest possible positive number. The least value (i.e. less than anything else) is probably -Number.MAX_VALUE. Jun 10 '14 at 23:19
• This is the maximum floating point value. The question is about the highest integer value. And while Number.MAX_VALUE is an integer, you can't go past 2^53 without losing precision. Jul 22 '14 at 22:01
• ES6 introduces Number.MIN_SAFE_INTEGER and Number.MAX_SAFE_INTEGER Aug 31 '14 at 15:23

It is 253 == 9 007 199 254 740 992. This is because Numbers are stored as floating-point in a 52-bit mantissa.

The min value is -253.

This makes some fun things happening

Math.pow(2, 53) == Math.pow(2, 53) + 1
>> true

And can also be dangerous :)

var MAX_INT = Math.pow(2, 53); // 9 007 199 254 740 992
for (var i = MAX_INT; i < MAX_INT + 2; ++i) {
// infinite loop
}

• though one would never reach the end of that for loop in a sane timeframe, you may wish to say i += 1000000000 Jul 8 '15 at 20:18
• @ninjagecko, he starts at MAX_INT so the end is right there. Also using i+= 1000000000 would make it no longer an infinite loop. Try it. Jan 5 '16 at 0:52
• @TedBigham: Ah oops, was ready too quickly through that. Thanks for correcting me twice. Jan 5 '16 at 8:34
• See Jimmy's argument for 9,007,199,254,740,991 instead of 9,007,199,254,740,992 here. That, combined with my follow-up, seems persuasive. Sep 29 '18 at 17:19

In JavaScript, there is a number called Infinity.

Examples:

(Infinity>100)
=> true

// Also worth noting
Infinity - 1 == Infinity
=> true

Math.pow(2,1024) === Infinity
=> true

This may be sufficient for some questions regarding this topic.

• Something tells me infinity doesn't qualify as an integer. :) Sep 19 '12 at 22:20
• But it's good enough to initialize a min variable when you're looking for a minimum value. Oct 23 '12 at 21:30
• Note that Infinity - 1 === Infinity Oct 18 '13 at 9:22
• also (Infinity<100) => false and Math.pow(2,1024) === Infinity Oct 30 '13 at 12:12
• Also worth nothing that it does handle negative Infinity too. So 1 - Infinity === -Infinity Nov 5 '14 at 21:51

Jimmy's answer correctly represents the continuous JavaScript integer spectrum as -9007199254740992 to 9007199254740992 inclusive (sorry 9007199254740993, you might think you are 9007199254740993, but you are wrong! Demonstration below or in jsfiddle).

console.log(9007199254740993);

However, there is no answer that finds/proves this programatically (other than the one CoolAJ86 alluded to in his answer that would finish in 28.56 years ;), so here's a slightly more efficient way to do that (to be precise, it's more efficient by about 28.559999999968312 years :), along with a test fiddle:

/**
* Checks if adding/subtracting one to/from a number yields the correct result.
*
* @param number The number to test
* @return true if you can add/subtract 1, false otherwise.
*/
var numMinusOne = number - 1;
var numPlusOne = number + 1;

return ((number - numMinusOne) === 1) && ((number - numPlusOne) === -1);
}

//Find the highest number

//Get a number higher than the valid integer range
highestNumber *= 2;
}

//Find the lowest number you can't add/subtract 1 from
var numToSubtract = highestNumber / 4;
while (numToSubtract >= 1) {
highestNumber = highestNumber - numToSubtract;
}

numToSubtract /= 2;
}

//And there was much rejoicing.  Yay.
console.log('HighestNumber = ' + highestNumber);

• @CoolAJ86: Lol, I'm looking forward to March 15, 2040. If our numbers match we should throw a party :) Feb 12 '13 at 22:15
• var x=Math.pow(2,53)-3;while (x!=x+1) x++; -> 9007199254740991 Nov 17 '13 at 23:18
• @MickLH: I get 9007199254740992 with that code. What JavaScript engine are you using to test? Nov 18 '13 at 15:52
• You get 9007199254740992 with your own code, I did not use the final value of x, but the final evaulation of x++ for paranoid reasons. Google Chrome btw. Nov 18 '13 at 18:00
• @MickLH: evaluating x++ gives you the value of x before the increment has occurred, so that probably explains the discrepancy. If you want the expression to evaluate to the same thing as the final value of x, you should change it to ++x. Nov 24 '13 at 7:51

To be safe

var MAX_INT = 4294967295;

Reasoning

I thought I'd be clever and find the value at which x + 1 === x with a more pragmatic approach.

My machine can only count 10 million per second or so... so I'll post back with the definitive answer in 28.56 years.

If you can't wait that long, I'm willing to bet that

• Most of your loops don't run for 28.56 years
• 9007199254740992 === Math.pow(2, 53) + 1 is proof enough
• You should stick to 4294967295 which is Math.pow(2,32) - 1 as to avoid expected issues with bit-shifting

Finding x + 1 === x:

(function () {
"use strict";

var x = 0
, start = new Date().valueOf()
;

while (x + 1 != x) {
if (!(x % 10000000)) {
console.log(x);
}

x += 1
}

console.log(x, new Date().valueOf() - start);
}());
• cant you just start it at 2^53 - 2 to test? (yes you can, I just tried it, even with -3 to be safe: var x=Math.pow(2,53)-3;while (x!=x+1) x++;) -> 9007199254740991 Nov 17 '13 at 23:14
• Nice answer! Moreover, I know the value is settled, but why not use binary search for its finding? Mar 3 '14 at 18:22
• What's the fun in that? Besides, @Briguy37 beat me to it: stackoverflow.com/a/11639621/151312 Mar 4 '14 at 19:04
• note that this 'safe' MAX_INT based on 32 bits will not work when comparing with Date values. 4294967295 is so yesterday! May 20 '14 at 22:08
• The answer "To be safe: var MAX_INT = 4294967295;" isn't humorous. If you're not bitshifting, don't worry about it (unless you need an int larger than 4294967295, in which case you should probably store it as a string and use a bigint library). Dec 27 '14 at 19:43

Many earlier answers have shown 9007199254740992 === 9007199254740992 + 1 is true to verify that 9,007,199,254,740,991 is the maximum and safe integer.

But what if we keep doing accumulation:

input: 9007199254740992 + 1  output: 9007199254740992  // expected: 9007199254740993
input: 9007199254740992 + 2  output: 9007199254740994  // expected: 9007199254740994
input: 9007199254740992 + 3  output: 9007199254740996  // expected: 9007199254740995
input: 9007199254740992 + 4  output: 9007199254740996  // expected: 9007199254740996

We can see that among numbers greater than 9,007,199,254,740,992, only even numbers are representable.

It's an entry to explain how the double-precision 64-bit binary format works. Let's see how 9,007,199,254,740,992 be held (represented) by using this binary format.

Using a brief version to demonstrate it from 4,503,599,627,370,496:

1 . 0000 ---- 0000  *  2^52            =>  1  0000 ---- 0000.
|-- 52 bits --|    |exponent part|        |-- 52 bits --|

On the left side of the arrow, we have bit value 1, and an adjacent radix point. By consuming the exponent part on the left, the radix point is moved 52 steps to the right. The radix point ends up at the end, and we get 4503599627370496 in pure binary.

Now let's keep incrementing the fraction part with 1 until all the bits are set to 1, which equals 9,007,199,254,740,991 in decimal.

1 . 0000 ---- 0000  *  2^52  =>  1  0000 ---- 0000.
(+1)
1 . 0000 ---- 0001  *  2^52  =>  1  0000 ---- 0001.
(+1)
1 . 0000 ---- 0010  *  2^52  =>  1  0000 ---- 0010.
(+1)
.
.
.
1 . 1111 ---- 1111  *  2^52  =>  1  1111 ---- 1111.

Because the 64-bit double-precision format strictly allots 52 bits for the fraction part, no more bits are available if we add another 1, so what we can do is setting all bits back to 0, and manipulate the exponent part:

┏━━▶ This bit is implicit and persistent.
┃
1 . 1111 ---- 1111  *  2^52      =>  1  1111 ---- 1111.
|-- 52 bits --|                     |-- 52 bits --|

(+1)

1 . 0000 ---- 0000  *  2^52 * 2  =>  1  0000 ---- 0000. * 2
|-- 52 bits --|                     |-- 52 bits --|
point has no way to go, but
there is still one 2 left in
exponent part)
=>  1 . 0000 ---- 0000  *  2^53
|-- 52 bits --|

Now we get the 9,007,199,254,740,992, and for the numbers greater than it, the format can only handle increments of 2 because every increment of 1 on the fraction part ends up being multiplied by the left 2 in the exponent part. That's why double-precision 64-bit binary format cannot hold odd numbers when the number is greater than 9,007,199,254,740,992:

(consume 2^52 to move radix point to the end)
1 . 0000 ---- 0001  *  2^53  =>  1  0000 ---- 0001.  *  2
|-- 52 bits --|                 |-- 52 bits --|

Following this pattern, when the number gets greater than 9,007,199,254,740,992 * 2 = 18,014,398,509,481,984 only 4 times the fraction can be held:

input: 18014398509481984 + 1  output: 18014398509481984  // expected: 18014398509481985
input: 18014398509481984 + 2  output: 18014398509481984  // expected: 18014398509481986
input: 18014398509481984 + 3  output: 18014398509481984  // expected: 18014398509481987
input: 18014398509481984 + 4  output: 18014398509481988  // expected: 18014398509481988

How about numbers between [ 2 251 799 813 685 248, 4 503 599 627 370 496 )?

1 . 0000 ---- 0001  *  2^51  =>  1 0000 ---- 000.1
|-- 52 bits --|                |-- 52 bits  --|

The value 0.1 in binary is exactly 2^-1 (=1/2) (=0.5) So when the number is less than 4,503,599,627,370,496 (2^52), there is one bit available to represent the 1/2 times of the integer:

input: 4503599627370495.5   output: 4503599627370495.5
input: 4503599627370495.75  output: 4503599627370495.5

Less than 2,251,799,813,685,248 (2^51)

input: 2251799813685246.75   output: 2251799813685246.8  // expected: 2251799813685246.75
input: 2251799813685246.25   output: 2251799813685246.2  // expected: 2251799813685246.25
input: 2251799813685246.5    output: 2251799813685246.5
/**
Please note that if you try this yourself and, say, log
these numbers to the console, they will get rounded. JavaScript
rounds if the number of digits exceed 17. The value
is internally held correctly:
*/

input: 2251799813685246.25.toString(2)
output: "111111111111111111111111111111111111111111111111110.01"
input: 2251799813685246.75.toString(2)
output: "111111111111111111111111111111111111111111111111110.11"
input: 2251799813685246.78.toString(2)
output: "111111111111111111111111111111111111111111111111110.11"

And what is the available range of exponent part? 11 bits allotted for it by the format.

From Wikipedia (for more details, go there) So to make the exponent part be 2^52, we exactly need to set e = 1075.

The short answer is “it depends.”

If you’re using bitwise operators anywhere (or if you’re referring to the length of an Array), the ranges are:

Unsigned: 0…(-1>>>0)

Signed: (-(-1>>>1)-1)…(-1>>>1)

(It so happens that the bitwise operators and the maximum length of an array are restricted to 32-bit integers.)

If you’re not using bitwise operators or working with array lengths:

Signed: (-Math.pow(2,53))…(+Math.pow(2,53))

These limitations are imposed by the internal representation of the “Number” type, which generally corresponds to IEEE 754 double-precision floating-point representation. (Note that unlike typical signed integers, the magnitude of the negative limit is the same as the magnitude of the positive limit, due to characteristics of the internal representation, which actually includes a negative 0!)

• This is the answer I wanted to stumble upon on how to convert X to a 32 bit integer or unsigned integer. Upvoted your answer for that. Nov 24 '13 at 2:51

ECMAScript 6:

Number.MAX_SAFE_INTEGER = Math.pow(2, 53)-1;
Number.MIN_SAFE_INTEGER = -Number.MAX_SAFE_INTEGER;
• Beware this is not (yet) supported by all browsers! Today iOS (not even chrome), Safari and IE don't like it. May 6 '15 at 22:45
• Please read the answer carefully, we are not using the default implementation of Number.MAX_SAFE_INTEGER in ECMAScript 6, we are defining it by Math.pow(2, 53)-1 May 8 '15 at 1:17
• I thought it was just a reference to how it is implemented in ECMA 6! :P I think my comment is still valid, though. All a matter of context. ;) May 8 '15 at 1:24
• Is it reliable to calculate MAX_SAFE_INTEGER in all browsers by working backwards? Should you move forwards instead? I.e., Number.MAX_SAFE_INTEGER = 2 * (Math.pow(2, 52) - 1) + 1;
– kjv
May 26 '15 at 18:45
• Is Math.pow(2, 53)-1 a safe operation? It goes one larger than the largest safe integer. Mar 13 '17 at 3:09

Other may have already given the generic answer, but I thought it would be a good idea to give a fast way of determining it :

for (var x = 2; x + 1 !== x; x *= 2);
console.log(x);

Which gives me 9007199254740992 within less than a millisecond in Chrome 30.

It will test powers of 2 to find which one, when 'added' 1, equals himself.

• It might crash your application, thought. Nov 14 '19 at 1:51

Anything you want to use for bitwise operations must be between 0x80000000 (-2147483648 or -2^31) and 0x7fffffff (2147483647 or 2^31 - 1).

The console will tell you that 0x80000000 equals +2147483648, but 0x80000000 & 0x80000000 equals -2147483648.

Try:

maxInt = -1 >>> 1

In Firefox 3.6 it's 2^31 - 1.

• @danorton: I'm not sure you understand what you are doing. ^means raised to the power. In the javascript console, ^ is XOR, not raised-to Dec 24 '13 at 11:09
• open Chrome/Firefox console. Type 5^2. In binary, 5 is 101 and 2 is 010. Now, if you Bitwise XOR them, you'll get 5(101) ^ 2(010) = 7(111) READ THIS IF YOU'RE CONFUSED What is being discussed here is Math.pow() not the ^ operator Dec 25 '13 at 15:22
• Again, I am not at all confused. I have commented and downvoted on what is written. If Math.pow() is what is meant, then that is what should be written. In an answer to a question about JavaScript, it is inappropriate to use syntax of a different language. It is even more inappropriate to use a syntax that is valid in JavaScript, but with an interpretation in JavaScript that has a different meaning than what is intended. Dec 31 '13 at 18:56
• 2^31 is how one writes two to the thirty-first power in English. It's not in a code block. Would you complain about someone using a ; in an answer, because that's a character with a different meaning in Javascript?
– lmm
Mar 5 '14 at 13:55
• Even though one should write 2³¹ and not 2^31 in plain text its common to do so, because most keyboard layouts doesn't have those characters by default. At least I did not have any problems understanding what was meant in this answer. Jun 2 '15 at 21:07

JavaScript has received a new data type in ECMAScript 2020: BigInt. It introduced numerical literals having an "n" suffix and allows for arbitrary precision:

var a = 123456789012345678901012345678901n;

Precision will still be lost, of course, when such big integer is (maybe unintentionally) coerced to a number data type.

And, obviously, there will always be precision limitations due to finite memory, and a cost in terms of time in order to allocate the necessary memory and to perform arithmetic on such large numbers.

For instance, the generation of a number with a hundred thousand decimal digits, will take a noticeable delay before completion:

...but it works.

I did a simple test with a formula, X-(X+1)=-1, and the largest value of X I can get to work on Safari, Opera and Firefox (tested on OS X) is 9e15. Here is the code I used for testing:

• Note that 9e15 = 2^53 (see @Jimmy's answer). Nov 21 '08 at 0:39
• 9e15 = 9000000000000000. 2^53 = 9007199254740992. Therefore to be pedantic, 9e15 is only approximately equal to 2^53 (with two significant digits). Sep 19 '12 at 22:24
• @chaiguy In 9000000000000000 there is 1 significant figure. in ` 9007199254740992` there are 15 significant figures. Nov 13 '13 at 6:36
• @RoyiNamir Not wanting to start a pointless argument here, but 9000000000000000 has 16 significant digits. If you want only 1, it would have to be written as 9x10^15. Nov 13 '13 at 18:01
• @chaiguy No. 9000000000000000 as it is - has 1 SF. where 90*10^14 has 2. (sigfigscalculator.appspot.com) & mathsfirst.massey.ac.nz/Algebra/Decimals/SigFig.htm (bottom section) Nov 13 '13 at 18:17

I write it like this:

var max_int = 0x20000000000000;
var min_int = -0x20000000000000;
(max_int + 1) === 0x20000000000000;  //true
(max_int - 1) < 0x20000000000000;    //true

Same for int32

var max_int32 =  0x80000000;
var min_int32 = -0x80000000;

Let's get to the sources

Description

The MAX_SAFE_INTEGER constant has a value of 9007199254740991 (9,007,199,254,740,991 or ~9 quadrillion). The reasoning behind that number is that JavaScript uses double-precision floating-point format numbers as specified in IEEE 754 and can only safely represent numbers between -(2^53 - 1) and 2^53 - 1.

Safe in this context refers to the ability to represent integers exactly and to correctly compare them. For example, Number.MAX_SAFE_INTEGER + 1 === Number.MAX_SAFE_INTEGER + 2 will evaluate to true, which is mathematically incorrect. See Number.isSafeInteger() for more information.

Because MAX_SAFE_INTEGER is a static property of Number, you always use it as Number.MAX_SAFE_INTEGER, rather than as a property of a Number object you created.

Browser compatibility In JavaScript the representation of numbers is 2^53 - 1.

• This is an important point. It is why I am here googling max int size. Other answers suggest 53 bits, so I coded it up thinking I could do bit wise arithmetic of positive values safely up to 52 bits. But it failed after 31 bits. Thanks @Marwen Mar 8 '21 at 1:03

In the Google Chrome built-in javascript, you can go to approximately 2^1024 before the number is called infinity.

Scato wrotes:

anything you want to use for bitwise operations must be between 0x80000000 (-2147483648 or -2^31) and 0x7fffffff (2147483647 or 2^31 - 1).

the console will tell you that 0x80000000 equals +2147483648, but 0x80000000 & 0x80000000 equals -2147483648

Hex-Decimals are unsigned positive values, so 0x80000000 = 2147483648 - thats mathematically correct. If you want to make it a signed value you have to right shift: 0x80000000 >> 0 = -2147483648. You can write 1 << 31 instead, too.

Firefox 3 doesn't seem to have a problem with huge numbers.

1e+200 * 1e+100 will calculate fine to 1e+300.

Safari seem to have no problem with it as well. (For the record, this is on a Mac if anyone else decides to test this.)

Unless I lost my brain at this time of day, this is way bigger than a 64-bit integer.

• its not a 64 bit integer, its a 64-bit floating point number, of which 52/53 bits are the integer portion. so it will handle up to 1e300, but not with exact precision. Nov 21 '08 at 18:11
• Jimmy is correct. Try this in your browser or JS command line: 100000000000000010 - 1 => 100000000000000020
– Ryan
Oct 7 '11 at 21:54

Node.js and Google Chrome seem to both be using 1024 bit floating point values so:

Number.MAX_VALUE = 1.7976931348623157e+308
• -1: the maximum representable (non-exact integral) number may be ~2^1024, but that doesn't mean they're deviating from the IEEE-754 64-bit standard. Apr 3 '13 at 21:44
• MAX_INT? Do you mean MAX_VALUE? May 29 '13 at 9:54
• that's maximum of a floating point value. It doesn't mean that you can store an int that long Aug 4 '13 at 10:30
• Or more to the point, you can't reliably store an int that long without loss of accuracy. 2^53 is referred to as MAX_SAFE_INT because above that point the values become approximations, in the same way fractions are. Jun 16 '14 at 18:32